Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 47~52

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.17565

Analysis of Mathematical Communication of Students through AIR Model

Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 47~52

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.17565

whose effectiveness is through three situations, namely Auditory (hearing), Intellectually (thinking), and Repetition. As a result, students get deeper abilities regarding creativity, activeness, problem solving, and strong memory. The Cooperative Auditory Intellectually Repetition learning model can be explained according to its meaning. Auditory means related to hearing, such as listening to the information obtained. Intellectually means learning to overcome problems by trying or creating something new. Repetition means repeating what has been learnt.

From all the responses above, the researcher interprets the Cooperative Auditory Intellectually Repetition learning model as a learning style that links three points of view, namely auditory, intellectually, repetition, which means exploring the material, mastering the material, and stabilising the material by repetition in the form of tasks. The following are the stages in conducting the Cooperative Auditory Intellectually Repetition learning model, among others: (1) Auditory Stages; (2) Intellectually Stages; (3) Repetition Stages.

Agustiana (2017) argues that the Cooperative AIR learning model has some advantages and disadvantages. The first advantage, which is familiarising the function of hearing and creating the courage of students when sharing their opinions. Second, it provides opportunities for learners to solve problems in creative and innovative ways. Third, it familiarises learners to re-memorise the material that has been listened to at school. Fourth, the Cooperative AIR learning model forms students as individuals who are more enthusiastic in learning. As for the shortcomings, when implementing learning, it is done with a long time because it involves three aspects contained in the learning model, Auditory, Intellectually, and Repetition. In addition, with the learning model listed above, many of the learners cannot understand the material and commands directly, so it requires repetition of delivery until the learners understand.

Based on the above description, the researcher conducted a study on the analysis of mathematical communication of grade X students through Cooperative Auditory Intellectually Repetition (AIR) learning model at SMAN 1 Driyorejo Gresik. This research is expected to be applied in other learning and international-based schools. Research on the Cooperative Auditory Intellectually Repetitiom (AIR) learning model was also conducted by (Ain and Kamaluddin 2020; Alan and Afriansyah 2017; Apriliani 2020; Bonatua, Mulyono, and Febriandi 2021; Hidayati and Darmuki 2021; Kamsurya and Saputri 2020;

Nisarohmah, Rochmad, and Rosyida 2021; Permatasari and Sulistyaningtyas 2023; Rohayati 2018;

Sarniah, Anwar, and Putra 2019; Zulherman, Arifudin, and Pratiwi 2020) 2. RESEARCH METHOD

This research is a form of quantitative research using the Quasi Experimental Design method with Post-test Only Control Group Design classification. This study uses two classes, namely the experimental class and the control class. According to Sugiyono (2016, p. 76), the effect of treatment is tested with different methods using t-test statistics, with a picture as below:

Fig 1. Research implementation design

Description:

E : Experimental class through Cooperative AIR learning model K : Control class through Cooperative Jigsaw learning model O : Post-test

The population determined in the study was all students of class X SMAN 1 Driyorejo Gresik. Samples were taken in two classes including class X IPS 3 as the experimental class and class X IPS 4 as the control class. Before the research, both classes were given different learning models. The operation of

Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 47~52

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.17565

realized the test was that the experimental class is delivered with the AIR Cooperative learning model, while the control class is delivered through the application of the Cooperative Jigsaw type. Data collection was obtained by conducting a mathematical communication test of two description questions in both classes with the same number and questions. The scoring of mathematical communication test is presented in the form of the following table:

Table 1. Assessment of Mathematical Communication Test

Indicators Student Response about the Problem Value Writing down

everything known in the problem

Did not write everything known in the problem 0 Write down everything known in the question but many are

incomplete

1 Writing down everything known in the question but a little

incomplete

2 Write everything known in the question accordingly and

completely

3 Write down

everything that is asked

Did not write everything that was asked in the question 0 Write down everything that is questioned in the question,

but many are incomplete

1 Write down everything that is questioned in the question,

but a little incomplete

2 Write everything that is asked in the question appropriately

and completely

3 Write down

the answers to the questions distributed

Did not write down the answer 0

Writing inappropriate answers to the questions distributed 1 Writing answers according to the questions distributed but

less precise

2 Write the answer according to the question that was

distributed correctly

3 Write down

the

conclusions obtained from the answers to the questions distributed

Did not write the conclusion 0

Writing conclusions does not match the answers to the questions shared

1 Writing conclusions according to the answers to the

questions shared but not quite right

2 Write conclusions according to the answers to the questions

distributed

3 Source: (Siti Fitriani 2015)

The descriptive question test was initially run using a validity test and reliability test and then distributed to students. Validity and reliability testing was carried out with other classes, not experimental or control classes. Regarding the calculation results obtained 𝑟_{𝑐𝑜𝑢𝑛𝑡} > 𝑟_{𝑡𝑎𝑏𝑙𝑒}, so that both questions are valid. The results of the reliability calculation with the two-split technique are 𝑟₁₁= 0.608 which can be classified in high reliability. Furthermore, to test the data, it used normality test, homogeneity test, and finally hypothesis testing. The normality test required the Chi Kuadrat table in both classes to determine normally distributed data. The homogeneity test used the F table to find out homogeneous or inhomogeneous data. Hypothesis testing required t-test in order to find whether there is a difference in mathematical communication in the class with the AIR Cooperative learning model, as well as the class through the application of the Cooperative Jigsaw type.

3. RESULTS AND DISCUSSION

Based on the results of the assessment of students' mathematical communication tests in experimental and control classes, different calculation results were obtained. The results of the normality test calculation in both classes are compared with the following table.

Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 47~52

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.17565

Table 2. Mathematical Communication Test Results and Data Normality Test

Data Cooperative AIR

Model

Jigsaw Cooperative Model

Minimum Value 53 46

Maximum Value 98 98

Mean 84,58 78,61

Standard Deviation 12,22 13,13

𝝌_{𝒉𝒊𝒕𝒖𝒏𝒈}^𝟐 1,23 -7,32

𝝌_{𝒕𝒂𝒃𝒆𝒍}^𝟐 12,591 14,067

Number of students 36 36

According to Table 2 above, it is found that both classes are normally distributed. The class with AIR Cooperative model has a minimum value of 53 while the class with Jigsaw Cooperative model is 46.

For the maximum value, it has the same value of 98. The class with AIR Cooperative model had a mean value of 84.58, while the class with Jigsaw Cooperative model was 78.61. The mathematical communication score of the class with Cooperative AIR learning model is higher than the class through the application of Cooperative Jigsaw type.

After the tested data is normally distributed, proceed with testing homogeneity to check whether the experimental class and control class have homogeneous conditions. The calculation is evidenced in the following table.

Table 3. Data Homogeneity Test

Class Total Variance 𝑭_{𝒉𝒊𝒕𝒖𝒏𝒈} 𝑭_{𝒕𝒂𝒃𝒆𝒍}

Experiment 36 149,45

1,15 1,76

Control 36 172,44

From the calculation of table 3, it has been obtained 𝐹_{𝑐𝑜𝑢𝑛𝑡}=1.15 and 𝐹_{𝑡𝑎𝑏𝑙𝑒}=1.75 which means 𝐹_{𝑐𝑜𝑢𝑛𝑡} ≤ 𝐹_{𝑡𝑎𝑏𝑙𝑒}, so the data is homogeneous.

Hypothesis testing was done utilising t-test with the formulation that: 𝐻0: 𝜇1= 𝜇2 (there is no difference in mathematical communication between the class with Cooperative AIR learning model and the class through the application of Cooperative Jigsaw type). While, 𝐻₀: 𝜇₁≠ 𝜇₂ (there is a difference in mathematical communication between classes with AIR Cooperative learning model and classes through the application of Cooperative Jigsaw type). The following is a table of t-test data analysis results:

Table 4. Hypothesis Testing with t-Test

Class Total 𝑺_𝑮 𝒕_{𝒉𝒊𝒕𝒖𝒏𝒈} 𝒕_{𝒕𝒂𝒃𝒆𝒍}

Experiment 36

12,68 2,147 1,994

Control 36

Based on Table 4, we found that 𝑡_{ℎ𝑖𝑡𝑢𝑛𝑔} > 𝑡_{𝑡𝑎𝑏𝑒𝑙} or 𝐻₀ is rejected. This is because there are differences in students' mathematical communication in the experimental and control classes. In the data collection, this study used a sample of X IPS 3 class as an experimental class of 36 students and X IPS 4 class as a control class of 36 students with SPLTV material. To prove the effect of Cooperative AIR learning model, different treatments were given to the two classes. Furthermore, the data was tested using data normality test, homogeneity test, and hypothesis test. The experimental class used Cooperative AIR

Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 47~52

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.17565

model, while the control class used Cooperative Jigsaw model. Furthermore, a post-test was conducted with questions that had been tested for validity and reliability.

Based on Table 1, it is found that the average experimental class is 84.58 and the control class is 78.61.

So, it can be concluded that students in the experimental class have more maximum mathematical communication test scores. After the implementation of the data normality test and homogeneity test with the results of normal distribution and homogeneous data. According to the t-test data analysis obtained 𝑡_{ℎ𝑖𝑡𝑢𝑛𝑔}= 2.147 and with a classification of 0.05 obtained 𝑡_{𝑡𝑎𝑏𝑒𝑙}= 1.994, because 𝑡_{ℎ𝑖𝑡𝑢𝑛𝑔} >

𝑡𝑡𝑎𝑏𝑒𝑙 then 𝐻0 rejected, so there is a difference in mathematical communication between the class with the AIR Cooperative learning model and the Cooperative Jigsaw learning model class.

4. CONCLUSION

Based on the explanation above, students' mathematical communication with Cooperative AIR learning model is better than students' mathematical communication with Cooperative Jigsaw learning model. This is because the average value in the post-test of the experimental class, the class that applied the AIR Cooperative learning model, was more optimal than the control class, the class that applied the Jigsaw Cooperative learning model, namely the experimental class was 84.58, more optimal than the control class which was 78.61. According to the t-test data analysis, obtained t_hitung= 2.147 and t_tabel= 1.994, or t_hitung>t_tabel, then H_0 rejected. So, it can be concluded that there is an effect of Auditory Intellectually Repetition (AIR) Cooperative Learning Model on mathematical communication of class X students at SMAN 1 Driyorejo Gresik. Suggestions that can be given by the author for further research are the need to conduct research with other Cooperative Models, so that more learning models can be found or applied that can help students to think creatively and innovatively, with more efficient time.

ACKNOWLEDGEMENTS

My acknowledgments give to my parents for the support and facilities provided to me during my studies.

Besides that, special thanks for Universitas PGRI Adi Buana Surabaya, especially to Department of Mathematics Educationn. For may lecturers who have delivered me untik I graduated.

REFERENCES

[1] Agustiana, Elma. 2017. “Penerapan Model Pembelajaran Auditory, Intelectally, Repetition (AIR) Dengan Pendekatan Leson Study Terhadap Kemampuan Pemecahan Masalah Matematika Siwsa MTs 1 Lampung Selatan.” : 207.

[2] Ain, Nur, and Kamaluddin. 2020. “Pengaruh Model Pembelajaran Auditory Intellectually Repetition (AIR) Terhadap Kemampuan Berpikir Kritis Siswa Kelas X MAN Paso Pesisir.” Jurnal Pendidikan Fisika Tadulako Online (JPFT) 8(2): 40–44.

[3] Alan, Usman Fauzan, and Ekasatya Aldila Afriansyah. 2017. “Kemampuan Pemahaman Matematis Siswa Melalui Model Pembelajaran Auditory Intellectualy Repetition Dan Problem Based Learning.”

Jurnal Pendidikan Matematika 11(1).

[4] Apriliani, Vina. 2020. “Kemampuan Pemahaman Konsep Matematika Siswa SMP Melalui Penerapan Model Pembelajaran Auditory Intellectually Repetition.” Statmat : Jurnal Statistika Dan Matematika 2(2): 55.

[5] Bonatua, Dipa Sari, Dodik Mulyono, and Riduan Febriandi. 2021. “Penerapan Model Pembelajaran AIR (Auditory, Intellectualy, Repetition) Menggunakan Media Gambar Pada Pembelajaran Tematik Sekolah Dasar.” Jurnal Basicedu 5(5): 3850–57.

[6] Handayani, Vivin et al. 2022. “Model Pembelajaran Kooperatif Tipe Jigsaw Untuk Meningkatkan Pemahaman Konsep Peserta Didik.” Jurnal Sosial Humaniora Sigli 5(2): 125–30.

[7] Hidayati, Nur Alfin, and Agus Darmuki. 2021. “Penerapan Model Auditory Intellectually Repetition (AIR) Untuk Meningkatkan Kemampuan Berbicara Pada Mahasiswa.” Jurnal Educatio FKIP UNMA 7(1): 252–59.

[8] Kamsurya, Rizal, and Veni Saputri. 2020. “Influence of Auditory Intellectually Repetition (AIR) and Self Efficacy Learning Models on HOTS Problem-Based Problem Solving Ability.” Jurnal Ilmiah Mandala Education 6(2).

[9] Kemdikbud RI. 2020. “Panduan Pembelajaran Jarak Jauh.” Kementrian Pendidikan dan Kebudayaan (021): 28.

Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 47~52

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.17565

(AIR) Terhadap Kemampuan Komunikasi Matematis Peserta Didik Kelas VIII SMP N I Abung Barat Lampung Utara.”

[11] Nisarohmah, N I, R Rochmad, and Isnaini Rosyida. 2021. “The Effectiveness of Auditory, Intellectually and Repetition Learning with RME Approach to Students Mathematical Communication Ability.”

Journal of Primary Education 10(3): 179–93.

https://journal.unnes.ac.id/sju/index.php/jpe/article/view/46315%0Ahttps://journal.unnes.ac.id/sju/inde x.php/jpe/article/download/46315/19373.

[12] Permatasari, Berliana Putri, and Annisa Dwi Sulistyaningtyas. 2023. “Analysis of The Ability Student of SMA Al Islam Krian to Understanding Mathematical Concepts in Terms of Learning Styles Analysis of The Ability Student of SMA Al Islam Krian to Understanding Mathematical Concepts in Terms of Learning Styles.” (c).

[13] Ritonga, Sehat Matua. 2017. “AXIOM: Vol. VI, No. 1, Januari – Juni 2017, ISSN : 2087 - 8249.” VI(1):

1–10.

[14] Rohayati, Sri. 2018. “Penerapan Model Pembelajaran AIR Untuk Meningkatkan Kemampuan Komunikasi Matematika Siswa Sekolah Menengah Pertama.” Edumatica 08(01): 67–74.

[15] Sarniah, Siti, Chairul Anwar, and Rizki Wahyu Yunian Putra. 2019. “Pengaruh Model Pembelajaran Auditory Intellectually Repetition Terhadap Kemampuan Pemahaman Konsep Matematis.” Journal of Medives : Journal of Mathematics Education IKIP Veteran Semarang 3(1): 87.

[16] Siti Fitriani, Rayi. 2015. “Pengaruh Pembelajaran Koopertif Tipe Stad Terhadap Kemampuan Pemahaman Dan Komunikasi Matematis Siswa Sekolah Dasar.” Didaktik : Jurnal Ilmiah PGSD STKIP Subang 1(1): 128–41.

[17] Smp, Viii et al. 2019. “Jurnal Ilmiah Mahasiswa ( Pendidikan Matematika ) STKIP PGRI Bandar Lampung Pengaruh Model Pembelajaran Auditory , Intellectually , Repetition ( AIR ) Terhadap Kemampuan Pemecahan Masalah Matematika Siswa Kelas VII SMP Bhakti Mulya Suoh Lampung Barat Tuti.”

[18] Zulherman, Zulherman, Rahman Arifudin, and Melly Siska Pratiwi. 2020. “Pengaruh Model Pembelajaran Auditory, Intellectuality, Repetition (AIR) Untuk Siswa Sekolah Dasar.” Jurnal Basicedu 4(4): 1267–1266.

Indonesian Journal of Education & Mathematical Science Vol. 5, No. 1, Januari 2024, pp. 53~57

ISSN: 2721-3838, DOI: 10.30596/ijems.v5i1.16783

Android-Based Interactive Multimedia Development Using ISpring Suite